Old Guy said:
Thanks very much; can you expand a bit on your answer? Specifically, what does it mean for r to be "bounded", and how does it make the time average of a total time derivative go to zero? I understand about the "long time" bit, although even there it would seem to approach a limit of zero, and not actually equalling zero. Am I thinking about this right? Thanks again.
I'll expand and expound:
First of all, I'm discussing a single classical particle.
The particle travels along a trajectory
<br />
{\vec r}(t)<br />
under the influence of some forces.
When I say that r is bounded I mean that I can choose a "bound"--some (possibly large) number (R) such that I always have
<br />
r(t)<R\;,<br />
for all t. Put more simply, the particle never escapes off to infinity and is always within some finite (though perhaps large) distance from the origin. Also, Because r is bounded so too is r^2 bounded.
Next, I define the "time averaging" as
<br />
\langle\ldots\rangle\equiv<br />
\lim_{T\to\infty}\frac{1}{T}\int_0^Tdt(\ldots)<br />
So then
<br />
\langle \frac{d r^2}{dt}\rangle<br />
=\lim_{T\to\infty}\frac{1}{T}\int_0^T\frac{d r^2}{dt}<br />
=\lim_{T\to\infty}\frac{r^2(T)-r^2(0)}{T}\;.<br />
But that last quantity is necessarily less than
<br />
lim_{T\to\infty}<br />
\frac{R^2}{T}=0\;.<br />
(it's also necessarily greater than -R^2/T)
Thus, because the quantity r^2 was bounded the time-average of the derivative of r^2 was zero. This is true for any bounded quantity.
